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	<p>Their rodent research shows how certain genes are regulated in a part of the brain that controls the equilibrium of salt, water, energy, reproduction and other rhythms -- the hypothalamus. The scientists found that the gene patterns activated by stimulating an instinctive behavior, salt appetite, were the same groups of genes regulated by cocaine or opiate (such as heroin) addiction.</p>
<p>&quot;We were surprised and gratified to see that blocking addiction-related pathways could powerfully interfere with sodium appetite,&quot; said co-lead author Wolfgang Liedtke, M.D., Ph.D., an Assistant Professor of Medicine and Neurobiology at Duke University. &quot;Our findings have profound and far-reaching medical implications, and could lead to a new understanding of addictions and the detrimental consequences when obesity-generating foods are overloaded with sodium.&quot;</p>
<p>The study was published in the <em>Proceedings of the National Academy of Sciences </em>early edition online on July 11.</p>
<p>&quot;Though instincts like salt appetite are basically genetic neural programs, they may be substantially changed by learning and cognition,&quot; said co-lead author Professor Derek Denton, of the University of Melbourne and the Florey Neuroscience Institute, who is renowned for his pioneering work in the field of instinctive behavior. &quot;Once the genetic program is operating, experiences that are part of the execution of the program become embodied in the overall patterns of an individual's behavior, and some scientists have theorized that drug addiction may use nerve pathways of instinct. In this study, we have demonstrated that one classic instinct, the hunger for salt, is providing neural organization that subserves addiction to opiates and cocaine.&quot;</p>
<p>Deeply embedded pathways of an ancient instinct may explain why addiction treatment with the chief objective of abstinence is so difficult, said Denton. Liedtke said that this might be relevant given the appreciable success of maintenance approaches that don't involve abstinence, like replacing heroin with methadone and cigarettes with nicotine gum or patches.</p>
<p>&quot;The work opens new pathways of experimental approach to addiction,&quot; Denton said.</p>
<p>The study was the first to examine gene regulation in the hypothalamus for salt appetite. The team used two techniques to induce the instinctive behavior in mice -- they withheld salt for a while combined with a diuretic and they also used the stress hormone ACTH to increase salt needs.</p>
<p>Liedtke, who is also affiliated with the Duke Center for Translational Neuroscience and the Duke Pain Clinics, said the researchers were surprised that they could detect that genes were &quot;turned on&quot; or &quot;turned off&quot; in salt appetite, these patterns were often substantially reversed within ten minutes of the animals' drinking salt solution, well before any significant salt could be absorbed from the gut into the bloodstream. The question of how this occurs is perplexing, and opens an entirely new field for exploration, Liedtke said.</p>
<p>In terms of survival advantage of this behavior, fast satisfaction of salt appetite makes sense. Among wild animals, the ability to rapidly compensate for salt need by avidly lapping a salty solution means that depleted animals can drink to gratification and leave quickly, reducing their vulnerability to predators.</p>
<p>The Duke-Melbourne research team found that when the animal harbors a robust sodium appetite, a certain region of the hypothalamus seems to become susceptible to the effects of dopamine, which is the brain's internal currency for reward. That suggests that the state of the instinctive need, the sodium-depleted state, &quot;spring-loads&quot; the hypothalamus for the subjective experience of reward which follows when animals gratify the need -- a satisfied feeling. This concept is substantiated by their finding that the local actions of dopamine on a sub-region of the hypothalamus are critical for the animals' instinctive behavior.</p>
<p>Other Duke authors include Hao Zhang, Andreas Pfenning and Sarah Hochendoner. The Melbourne team included Michael McKinley, Andrew Lawrence, John Drago, and Lesley Walker of the Florey Neuroscience Institute. The team also included Donald Hilton of the University of Texas Health Science Center in San Antonio.</p>
<p>Support came from the G. Harold and Leila Y. Mather's Foundation, The Robert J Jr. and Helen C. Kleberg Foundation, the Search Foundation, Ms. Diana Gibson, Mr. Robert Albert, Mr. Baillieu Myer, and Dr. Mark Nelson, the NH&amp;MRC of Australia Fellowship, The Derek Denton Endowment Fund, a Trinity College Undergrad Fellowship, a Robert H. Ebert Clinical Scholarship of the Klingenstein Fund and start-up funds from Duke University.</p>

<a href="http://images.sciencedaily.com/2011/07/110711151451-large.jpg" rel="thumbnail"><img src="http://images.sciencedaily.com/2011/07/110711151451.jpg" height="389" width="300" border="0" alt="" /></a><br />
								<div id="caption" style="padding: 5px 0 10px 0"><em>Researchers induced salt (Na+) appetite in mice or rats, which led to the discovery of profound changes in certain nerve cells in the hypothalamus (micrographs, upper right). These nerve cells became enlarged and increased their expression of two proteins, DARPP-32 (green) and ARC (blue). These neurons are part of a powerful circuit that sustains addiction behavior, and the increased expression of DARPP-32 and ARC suggests that these neurons more readily respond to reward stimuli. The bright yellow color in these neurons indicates co-localization (the appearance together) of both of those proteins along with orexin, a protein initially linked to appetite stimulation, but in this part of the hypothalamus later found to be critical for addiction-related behaviors. Dopamine-receptor-1 is a nerve-cell-surface receptor protein that signals to the nerve cell that dopamine molecules have attached. One of the effects of dopamine binding to its receptor is that animals, including humans, get a strong reward sensation, which can be coupled to behavioral conditioning -- the binding makes the animal or person want to repeat what led to the dopamine release. Below, the line graphs show that induced salt appetite in mice can be powerfully reduced with drugs that block dopamine-receptor-1, whereas a related instinct, thirst for water, is not affected by such treatment. (Credit: Wolfgang Liedtke, Duke Departments of Medicine and Neurobiology)</em></div>
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